Temperature modulated desiccant evaporative cooler and indirect and direct evaporative air conditioning systems, methods, and apparatus

ABSTRACT

A method is disclosed for supplying air conditioned air to a residence or building interior. The method entails positioning a heat and mass exchanger to discharge conditioned air into the residence or building interior. Further, a rotatable desiccant wheel dehumidifier in positioned in fluid communication with the h 5 eat and mass exchanger. Supply air is received and treated in the dehumidifier, thereby supplying dry air to the heat and mass exchanger and exhausting hot humid air. The heat and mass exchanger is positioned and configured to received dry air from the dehumidifier and supply cooler dry air to the residence or building interior, or other target environment. A system is also disclosed for operating the described air supplying or air conditioning method.

BACKGROUND

The present application is a Divisional of U.S. patent application Ser. No. 14/461,962, filed on Aug. 18, 2014 (now allowed), which claims the benefit of U.S. Provisional Application Ser. No. 61/867,571, filed on Aug. 19, 2013 (expired), which disclosures are hereby incorporated by reference for all purposes and made a part of the present disclosure.

In one aspect, the present disclosure relates generally to systems and methods (and sub-processes and components thereof and therefor) for air conditioning a localized environment. The disclosure also relates to and introduces an improved indirect-direct evaporative air conditioner, methods of operating same, and systems and operations incorporating and/or employing same. In another aspect, the present disclosure relates to power generation and/or distribution, particularly for localized consumption. The disclosure relates to both a system and a method of, or for, power generation and/or distribution. The disclosure also relates to a system and method for meeting the energy demand of a localized environment.

The conventional system of centralized power generation and distribution over a wide geographic network is characterized by vast losses of energy either through thermal loss during production or distribution loss during delivery. It is estimated that only forty percent of the energy generated by such centralized plants in the United States actually make it to the consumer. This grossly inefficient model may be countered somewhat by electric power generating plants that generate power more closely to the consumer and utilizing the thermal energy that is generated as byproduct in electric power generation. In this regard, micro combined heat and power generation systems are available that co generate electricity and heat and utilize the heat on location.

Conventional electric driven air-conditioning systems typically utilize large compressors that are driven by AC inductive motors. These motors demand power for start up and for continuous operation. Reliance on the systems on hot summer days contributes to very high energy demand peaks on the electric grid and inefficiency on our general collective consumption of energy. Internal combustion engines (ICE) can be utilized to drive HVAC compressors directly and the thermal heat generated by the ICE can be used to heat water for domestic use, dehumidify the conditioned air using desiccants, to distill or purify water or to heat swimming pools or Jacuzzis, or in the case of businesses that use boilers, to preheat water for process heat or to generate steam. Small systems that are capable of generating up to 5 KW of electric power and heat simultaneously and at the same time, provide air conditioning are called Micro Combined Cooling Heating and Power (MCCHP) Systems.

Another application in which cogeneration is found is in Auxiliary Power Units (APU) for commercial long haul trucks. In the United States, these trucks are required by law to rest for ten hours after eleven hours of driving. APUs are designed to eliminate long idle rest stops. Similar to the MCCHP, the APU uses a small internal combustion engine (ICE), typically fueled by diesel, in lieu of the truck's main engine. Since this engine is much smaller than the main engine in terms of displacement, it uses a fraction of the fuel which would be otherwise required to idle the larger engine. These units can run for as much as eight hours on one US gallon of diesel. The engine provides heat to the main engine so that the main engine can be started easily. An APU can save up to 20 gallons of fuel a day, and can extend the useful life of a truck's main engine by around 100,000 miles, avoiding long idle times. APUs provide the truck cab with electrical power for hotel load requirements and may also include air-conditioning for the truck cab. Some APUs even provide an air compressor that maintains the trucks required supply of high pressure air for suspension, brakes and other requirements.

FIGS. 6-9 are illustrations of conventional HVAC systems including systems employing direct compression systems and systems employing various evaporative cooling sub-systems. These include indirect evaporative cooling and indirect evaporative cooling systems. The conventional systems also employ a heat and mass exchanger (e.g., one marketed by or as Coolerado). The heat and mass exchanger consists of a box that separates wet and dry air streams.

There are multiple disadvantages commonly attributed to the conventional air conditioning installations. For example, conventional direct compression cooling systems exhibit high energy consumption, high acquisition and installation cost, and the use of undesirable chemical refrigerants. Also, these systems generate contribute 70% to 80% of residential electrical costs during hot summer months and are the highest contributor to residential peak power demands from the public grid. Furthermore, these systems contribute large amounts of heat to the environment in densely populated cities. For these and a variety of other reasons, some of which are touched on in this disclosure, there remains a need to improve HVAC systems and methods, and more particularly, air conditioning systems and methods.

SUMMARY

Described is an improved system and method for air conditioning. Several embodiments are illustrated, including a system and method utilizing an indirect-direct evaporative air conditioner. Further embodiments also employ a desiccant wheel humidifying/dehumidifying service. In one particular aspect, an improved indirect direct evaporative air conditioner unit is disclosed as well as methods of operating said unit or a system utilizing the unit.

Both a system and a method are disclosed for supplying air conditioned air to a residence or building interior. The method entails positioning a heat and mass exchanger to discharge conditioned air into the residence or building interior. Further, a rotatable desiccant wheel dehumidifier in positioned in fluid communication with the heat and mass exchanger. Supply air is received and treated in the dehumidifier, thereby supplying dry air to the heat and mass exchanger and exhausting hot humid air. The heat and mass exchanger is positioned and configured to received dry air from the dehumidifier and supply cooler dry air to the residence or building interior, or other target environment.

In another aspect, a method is described for generating and distributing electric power for localized use. The method includes providing a substantially enclosed building having an air conditioning and ventilation unit for supplying cooled air within the building. The unit includes a closed loop circuit configured to operate a closed loop refrigeration cycle, including a compressor operable to compress a working fluid of the closed loop circuit. The method entails engaging an internal combustion engine with the compressor, and operating the internal combustion engine to drive the compressor, thereby transferring energy to the refrigeration cycle (and thus, to the localized environment). The method further includes engaging an electric motor with the compressor; and operating the electric motor to drive the compressor, thereby transferring energy to the refrigeration cycle.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a simplified schematic of the basic components of a power generation and distribution system according to the present disclosure;

FIG. 1B is a simplified schematic of an exemplary power generation and distribution system installation according to one embodiment of the present disclosure;

FIG. 2 is a simplified schematic of a power generation and distribution system installation according to an alternate embodiment;

FIG. 3 is a simplified flow chart of a process for generating power for localized consumption;

FIG. 4 is a simplified flow chart of yet another alternative process or method for generating power for a localized environment; and

FIGS. 5A-5E depict an exemplary market presentation including slides illustrating exemplary illustrations and exemplary components;

FIG. 6 is a schematic of a conventional direct compression HVAC system;

FIG. 7 is a diagrammatical view of a conventional evaporative cooling system;

FIG. 8 is simplified diagrammatical view of a conventional indirect evaporative cooling system;

FIGS. 9A-9C are various views of a heat and mass exchanger suitable for various embodiments of a system and method of the present disclosure;

FIG. 10 is a perspective view of a desiccant dehumidifier apparatus suitable for use with various embodiments of a system and method according to the present disclosure;

FIG. 11 a is simplified schematic of a desiccant dehumidifier system suitable for use with various embodiments of the present disclosure;

FIG. 12 is a simplified system diagram of a system employing waste heat and a desiccant dehumidifier-heat and mass exchanger installation to supply air conditioning to a residence, according to the present disclosure;

FIG. 13 is a simplified water flow chart for a desiccant-dehumidifer system according to the present disclosure;

FIG. 14 is a schematic of an exemplary fan location configuration for the system of FIG. 13;

FIG. 15 is a simplified schematic and air flow diagram for an air conditioning system employing “natural cooling” according to the present disclosure;

FIG. 16 is a simplified schematic and air flow diagram for a “super cooling” air conditioning system according to an alternate embodiment of the present disclosure;

FIG. 17 is a simplified schematic and air flow diagram for an air conditioning system employing direct evaporator cooling according to an alternate embodiment of the present disclosure;

FIG. 18 is a simplified schematic and air flow diagram utilizing heat pipes, according to the present disclosure;

FIGS. 19A-19E are detail views of a preferred core structure of an indirect direct evaporative air conditioner according to the present disclosure;

FIG. 20 is a simplified schematic of the air conditioner in FIG. 19 in air pass through operational mode according to the present disclosure;

FIG. 21 is a simplified schematic of the air conditioner in FIG. 19 in direct evaporative cooling mode according to the present disclosure;

FIG. 22 is a simplified system diagram of an air conditioning system employing the air conditioner and operational mode as illustrated in FIG. 21;

FIG. 23 is a simplified schematic of the air conditioner in FIG. 19 in indirect evaporative cooling (and dew point cooling) mode according to the present disclosure;

FIG. 24 is a simplified system diagram of an air conditioning system employing the air conditioner and operational mode as illustrated in FIG. 22, according to the present disclosure;

FIG. 25 is a simplified schematic of the air conditioner in FIG. 19 in indirect direct evaporative cooling mode according to the present disclosure;

FIG. 26 is a simplified schematic of the air conditioner in FIG. 19 in enthalpy (ERV) mode, according to the present disclosure;

FIG. 27 is a simplified diagram\schematic of an alternative system embodiment employing a closed loop liquid desiccant dehumidification vacuum cooler; and

FIG. 28 is a simplified diagram\schematic of an alternative system embodiment employing a closed indirect evaporative cooler, according to the present disclosure.

DETAIL DESCRIPTION

The present disclosure relates generally to an improved system and method for air conditioning. Several embodiments are illustrated, including a system and method utilizing an indirect-direct evaporative air conditioner and\or desiccant wheel. In one particular aspect, an improved indirect direct evaporative air conditioner unit is disclosed as well as methods of operating said unit or a system utilizing the unit.

The present also disclosure relates generally to a system and method for power generation and distribution, particularly for localized utilization or consumption. To illustrate aspects of the system and method, certain embodiments or applications described. Description of these embodiments or applications may be limited to localized environment largely defined by a residence or commercial building. It will become apparent to one skilled in the relevant engineering, architecture, or other technical art, that these aspects in part, or in their entirety, may be equally applicable to other settings and other applications.

In further exemplary applications, a system and method according to the disclosure provides a modular electric and internal combustion engine driven HVAC systems suitable for incorporation with an Auxiliary Power Unit (APU), such as that commonly used for idle reduction in class 8 freight trucks. In another exemplary application, such a system and method may be suitable for use in or with a combined cooling, heating, and power system, such as that employed in stationary applications for residential housing or commercial office buildings. Such a system for localized use is often referred to as a Micro Combined Cooling, Heating and Power System or MCCHP system.

FIG. 1 depicts an exemplary system installation 100 for generating and distributing power in a localized environment. The depicted system contains some of the basic components of the system. In this example, the localized environment is provided by a permanent residence (R) (or commercial office building) that is also connected to, and supplied by, the electrical grid (EG). As is typical with such environments, and well suited for the system installation of the disclosure, the residence (R) is characterized by one or more energy demand loads (L), including, for example, air condition cooling demand, electricity demand for ordinary lighting and appliances. In further applications and installations, the localized environment may also exhibit heating demands (as also described herein), for example, for space heating or preheating of hot water systems. It should be noted that when referring to the localized environment, e.g., a residence or a building, in describing the system, installation, or method of operation, components of the localized environment may include equipment, units, or systems not necessarily physically located within the physical boundaries or enclosure of the residence, building, or vehicle (or other localized enclosure or environment). Such auxiliary components or systems may be physically located, partially or entirely, apart from the residence, building, vehicle, and the like, but operably associated therewith and serving the demands of the localized environment.

To satisfy the requirements of the energy demand loads (L), the residence (R) may draw power from the electrical grid (EG). As known in the art, power is supplied from a low voltage transformer to the AC load panel (MP) of the residence (R), which may include a main panel and distribution panel connecting to the various loads in the physical residence. The exemplary system further includes a power generator (PG) that is operable to meet some or all the demand load (L) of the residence (R), temporarily or permanently in lieu of the electrical grid (EG). In one aspect of the disclosure, the power generator (PG) is a hybrid power generator that includes an internal combustion engine (ICE) as a prime mover and a motor generator (MG), both of which may be engaged to output power (i.e., rotating mechanical energy) for use by the residence (R). In preferred installations, such a hybrid power generator (PG) is selectively operational in at least a first mechanical drive mode in which the fuel consuming prime mover (ICE) is engaged and a second mechanical drive mode in which the DC motor generator (MG) is engaged. Such selective drive capability may be embodied in a drive assembly (DA) that is engageable with each of the engine (ICE), motor generator unit (MG) and the load (L).

In this installation, a fuel supply (F) such as natural gas, diesel, or propane may be supplied to the installation 100 for consumption by the power generator (PG). In a further aspect, the power generator (PG) may also be operable in a drive mode in which the internal combustion engine (ICE) also drives the motor generator to generate DC power. This DC output may be directed for storage by a battery bank (B) or to an inverter (I) for conversion to AC power. The AC power may, in turn, be directed to the main panel (MP) for use in the residence or in particular applications, to the electrical grid (EG) for distribution.

Thus, in one respect, the system installation 100 provides for a localized environment access to an energy source independent from the electrical grid. This energy source originates from fuel supplied to an internal combustion. Chemical energy is converted to mechanical energy that is then utilized in meeting a load requirement of the localized environment. Alternatively, the mechanical energy may be used to generate DC power to satisfy immediate loads demands of the localized environment, or to store in the battery bank. In the latter case, the energy stored may be used later to drive the engine (and generate energy for meeting the demand load).

In further installations, heat energy generated by operation of the power generator (PG) (i.e., from chemical reactions or mechanical processes within the engine) may also be transferred to the residence (R) to satisfy, at least partly, the energy demands of another load (L). For example, heat exhausted by the engine may be used to heat or preheat water in the HVAC system, pool water, or a water heater, or heat air used for space heating.

Referring now to FIG. 1B, an exemplary system installation 200 for a localized environment is shown servicing a house or residential unit (R). The system 200 preferably integrates a hybrid power generator with the energy demand loads of the residence, which may include a heating, ventilation, and air conditioning system (HVAC) as commonly utilized in these installation. The HVAC system features a compressor 4 compressing a refrigerant or working fluid. The installation also includes a low voltage household circuit for supplying electricity to household appliances and equipment, outlets, and lighting. The household circuit includes a main panel to which utility power from the electrical grid 13 is supplied, as generally known in the industry. In operational mode, the power generator drives the compressor 4 to increase refrigerant vapor pressure. For example, in the case of a common centrifugal compressor, the power generator drives the main shaft (and impeller) of the compressor.

In yet another aspect of the disclosure, the hybrid power generator employs two power sources each of which may be selectively engaged with the compressor 4. In this example, the power sources are an internal combustion engine 1 and a motor generator 3. The internal combustion engine 1 is preferably pad mounted and situated adjacent the outside of the house. The engine may be one of various designs that are commercially available. In certain preferred embodiments, the engine 1 is a natural gas or propane engine. One suitable internal combustion engine is natural gas engine from Kubota (Kubuta DG972) which is rated at 25 (power output). The power generator is preferably equipped with a drive assembly including an engine clutch 2 and belt drive 6 that operably engages the engine 1 with the compressor 4, when a compressor clutch 5 is engaged. The drive assembly, specifically engine clutch 2, can also engage engine 1 directly with the motor generator unit 3.

In this preferred installation, the motor generator is a DC high capacity started/generator such as ECycle. The motor generator 3 is connected with a DC regulator 8 and thus, a DC power supply. As shown in FIG. 1B, the installation further includes a DC bus 9 that serves both an inverter charger 12 and a battery bank 11, as well as providing an auxiliary DC power outlet 10 for other residential usage. The inverter charger 12 connects with the electrical power supply (i.e., electrical power grid 13) to deliver excess AC power to the grid or bring AC power to the DC bus for distribution. In further applications, renewable electricity generators (e.g., solar panels or wind turbines) may be integrated with the installation to deliver additional energy supply. In such cases, the inverter 12 may be utilized for receiving and converting the additional electricity source.

In a further exemplary system, an electrical control unit or ECU 15 is incorporated as the controller of the system and provides the logic (hardware and software) for activating the engine clutch 2 between the internal combustion engine 1 and the motor generator 3. With proper mutual engagement of the motor generator 3 and engine 1 via engine clutch 2, the ECU 15 initiates rotation of the motor generator 3 to start the internal combustion engine 1. The engine 1 will, according to the settings of its governor, which is also programmed within ECU 15, allow the engine 1 to throttle to a set rpm. At this operational setting, the engine 1 overcomes the motor generator 3. In this mode, the motor generator 3 generates and delivers DC power to the DC regulator 8 and preferably, to the battery bank 11 for charging.

As dictated by the demands of the installation, the ECU 15 activates compressor clutch 5 to engage the AC Compressor 4. The hybrid power generator then drives the compressor 4, thereby transferring energy to the HVAC system of the residence. In normal operation, the engine 1 will drive the compressor 4 to compress the working fluid of the HVAC system as required by the appropriate closed loop refrigerant cycle. As determined by the ECU 15 (and as programmed by the user), the engine clutch 2 may simply be disengaged from the motor generator 3. Power provided from battery bank 11 may then be used to run motor generator 3 and thereby, drive the compressor 4. In certain applications, the choice of drive will be done automatically via the electronic control module (to optimize efficiency) or manually (by the operator to comply with noise and emissions regulatory issues). Factors or criteria determining which drive mode to employ include the availability of electrical power from the battery bank or the grid, fuel supply status for the engine for the engine, as well as the demand load presented by the residence. In any event, the ECU 15 may be programmed or configured to receive and/or process input representative of these factors, and determine the various drive modes of the power generator.

While motor generator 3 is engaged and operating as a DC generator, its voltage is regulated to 14, 48 or 56 volts and sent to a DC Bus 9 which in turn, provide powers for DC loads within the installation. Alternatively, it can provide DC power to inverter 12 and provide AC loads to the application or to the electric grid (for a fee or subsidy used by the local utility. A small battery bank 11 preferably stores power and makes power available to start the motor generator 3. Further, the battery bank 11 may be utilized to provide a supplemental power needed to accommodate for DC or AC load spikes.

In preferred applications, the load from the generator is provided as a DC load so as to allow other DC loads from renewable power sources to feed in to the DC bus and share a common Inverter. ECU 15 may be connected with inverter charger 12 to monitor AC current load demand so that it may start the generator 3 in the event that the load so requires. Furthermore, the inverter charger 12 may provide an additional source of DC power to the DC bus, which may then be used to charge the battery bank 11.

With reference now to FIG. 2, a further and alternative installation according to the disclosure incorporates a closed loop heating circulation system. The installation utilizes heat generated in the operation of the engine for satisfying, at least partially, further energy demands of the residence. In the specific installation illustrated, heat generated by the engine is used to preheat or heat furnace water or hot water systems. An exhaust heat exchanger installed and positioned in fluid communication with the exhaust side of the engine's circulation cooling system (as schematically represented in FIG. 2) is preferably employed to transfer heat generated by the engine. In this embodiment depicted by FIG. 2, a water circulation line is connected with a process dehumidification unit and/or furnace or hot water heater. Thus, in a further example, the circulation line passes cool water through coils of the heat exchanger, whereby heat is transferred from the engine's circulation to the cooler residential circulation water line. The heat is then passed to the demand for such use as pre-heating the furnace water or water for the water heater.

In the case of an APU application, the hybrid power generator may be implemented for the purpose of helping the system meet operational restrictions or noise or emissions. By simply engaging the electric motor to drive the ac compressor, using available battery power, the level of noise or emissions normally generated would be reduced (from that generated by internal combustion engine or other auxiliary power generator commonly employed by commercial long haul trucks.

Exemplary Component Descriptions

The descriptions below are provided to illustrate the types or specifications for various components suitable for incorporation into one or preferred embodiments of the system (operation of these exemplary systems). The component descriptions are provided for illustration only, and shall not be construed as limiting the disclosure and its concepts.

Internal combustion engine: Prime mover for the generator an or the HVAC compressor, may be a KUBOTA Engine or similar.

Motor/generator: provide power to start Internal combustion engine and/or the compressor or other equipment. This unit may also act as a generator when overcome by the engine, may be an ECycle brushless motor.

Inverter/charger: This unit converts DC power to AC and preferably incorporates power islanding features, charging capabilities, power monitoring capabilities and automatic transfer switch. Suitable models include the XANTREX or Schneider model 60048 On Grid and Off Grid Inverter.

Battery bank: May be AGM, Deep Cell or another battery capable of producing as much as 100 ah or more at 48 volts or 200 ah or more at 24 volts or 400 amp hours or more at 12 volts. Most battery types available in the market are suitable, including those suitable for golf cart or marine applications.

DC Regulator: capable of regulating the output voltage of the DC motor to 48, 24 or 12 volts, may be manufactured by America Power Systems Inc.

Engine clutch: magnetic clutch similar to those used in vehicular HVAC compressor systems.

Compressor clutch: magnetic clutch similar to those used in vehicular HVAC compressor systems.

ECU: capable of multiple analog and digital Inputs and Outputs similar to those found on DC generators such as the Deep Sea 4700 series controller.

Exemplary Power Generator Operations

The flow chart of FIG. 3 illustrates steps associated with at least one exemplary method of power generation and/or distribution according to the disclosure. The method is applicable to and associated with a localized environment having demand loads, such as a stationary environment in the form of a residence or commercial office building, or a truck having a main propulsion engine and an APU. The process represented by the flow chart is provided for illustration and to highlight various important capabilities of a preferred system and method.

A preferred method entails providing such a localized environment having a demand load such as an air conditioning unit. The air conditioning unit includes an AC compressors, as described above. An internal combustion engine is situated in or about the localized environment (52) and preferably, selectively and/or detachably engageable with the AC compressor to drive the compressor, thereby transferring mechanical energy to the compressor (54). This also transfers energy to the refrigeration cycle operable by or through the air conditioning system, and more specifically, the working fluid of the cycle. In this exemplary method, a DC motor generator is operated to initiate or start the engine. The engine is further driven to a predetermined setting (i.e., set RPM), at which point the motor generator begins to generate DC power (e.g., the motor is overcome by the engine (56)). In further embodiments, the DC power generated may be communicated forward and utilized within the localized environment (e.g., provide a DC power supply to household equipment). In further applications, the DC power may be used to charge a battery bank and alternatively, the battery pack may supply DC power to the motor generator for driving the AC compressor or for initiating start-up of the internal combustion engine. In a further exemplary step, the internal combustion engine may be disengaged from the AC compressor and the motor generator engaged to drive the AC compressor, instead 58. In this mode, the motor generator is driven by DC power supplied by the battery bank.

In one respect, the present disclosure teaches generating power for a localized environment, or more specifically, converting and transferring energy for ultimate consumption by or in the localized environment. In this way, energy is transferred to meet a load (energy) demand of the localized environment. In certain of the embodiments discussed above, chemical energy in the fuel supply is converted to mechanical or rotational energy (in the internal combustion engine). In specific examples, mechanical energy in the engine is used to rotationally drive the compressor, which in turn compresses the working fluid, thereby transferring the mechanical energy to the working fluid and for use in the refrigeration cycle.

Referring to FIG. 4, a basic process embodied by various applications further involves the utilization of stored energy in the battery bank to turn the motor generator unit (62). Functioning as a starter, the motor generator cranks the internal combustion engine, thereby facilitating its start-up and generating mechanical or rotating energy therein. This mechanical energy is then applied to drive a compressor or other equipment serving the localized environment 64, effectively transferring the generated energy to meet demand load of the localized environment.

FIG. 5 are excerpts from a proposed marketing power point presentation, which provides yet further examples of preferred embodiments of the disclosed systems and methods. The presentation describes benefits associated with implementation of the systems and methods, as well as components and equipment that are likely to be well suited for incorporation with these systems and methods.

Systems and Methods for Air Conditioning

FIGS. 6-9 are simplified illustrations of systems for heating and cooling a habitable space, such as a residence, office location, or equipment and product storage. These conventional technologies are provided herein as background and to help illustrate and highlight the particular contributions described herein. FIGS. 10-26 are simplified illustrations of improved systems and methods (and components, apparatus, and subprocesses therefor) for air conditioning a local environment, according to the present disclosure. It is contemplated, however, that the most suitable or most advantageous installations for the described systems will be a residential unit or commercial building. Accordingly, the Figures and descriptions are provided, for illustration only, in the context of a residence requiring the typical heating, cooling, and power needs. The system and method improvements addresses one or more of the disadvantages and deficiencies of conventional systems.

Table 1 and Table 2 below outlines problems attributable to conventional evaporative cooing and indirect evaporative cooling, respectively.

TABLE 1 Common Disadvantages of Conventional Cooling Systems Conventional Evaporative Cooling Uses inexpensive, natural water evaporation to cool However: Not effective enough in humid environments Dampens the air while cooling Theoretic drying limit to Wet Bulb Temp Indirect Evaporative Cooling Uses inexpensive, natural water evaporation to cool air without adding moisture to the air process However: Not effective enough in Humid environments Theoretic drying limit to dew point temperature

Various preferred embodiments of the system and\or method employ, among other things, combinations of indirect evaporative cooling, vacuum evaporative cooling, desiccant wheel dehumidification, water pre-conditioning, and\or heat modulation of working air to achieve objectives. Such combinations are featured in the systems depicted in FIGS. 10-26. Depending on the specific embodiment, the resulting system advantages include the following:

-   -   Lower acquisition and installation costs     -   50 to 90% energy savings     -   Lower maintenance costs     -   Lower or no use of ozone depleting refrigerants     -   Higher admittance of healthier fresh outside air     -   No excess heat contributed to exterior environment     -   Natural process involving water and natural desiccants (salt)     -   The hotter it gets the more efficient the cooling

Various embodiments employ increased evaporation and cooling techniques that achieve various operational features. Table 2 below provides a list of some of the techniques implemented. FIGS. 10-26 show exemplary system configurations wherein one or more of these techniques are employed.

TABLE 2 Evaporation and Cooling Techniques Employed in FIGS. 10-26 Increase Evaporation Air Flow Modulated Pre Heating of working air Increased Evaporation Surface Dehumidification of working and process air Water (refrigerant) Treatment Creation of Vacuum to reduce evaporation area pressure

It should be noted that the described systems and methods are also well suited to incorporate or utilize various energy sources, including systems previously described (i.e., in respect to FIGS. 1-5). The following are a few examples of such energy sources:

-   -   Combined Heat and Power     -   Solar Photo Voltaic and Heating     -   Waste Heat     -   Natural Gas and other Fossil Fuels     -   The system configuration of FIG. 12 illustrates an exemplary         residential installation utilizing a common energy sources         (natural gas) to serve a power unit that ultimately provides         electrical power to the residence. This particular system         utilizes, however, “extra” energy sources within the residence.         In this embodiment, excess heat from the power unit is used by         the hot water heater. Further, the residence' hot water heater         is incorporated with the dehumidifier and ultimately, the heat         and mass exchanger for cooling the residence as indicated by         lines 6000 a and 6000 b.

The schematic of FIGS. 13 and 14 illustrates the use of a desiccant wheel and heat and mass exchanger with the power unit. The unit serves as a hot water source for desiccant reactivation. The heat and mass exchanger is positioned downstream of the desiccant wheel and conditions air flow received therefrom prior to supplying the residence. In these examples, the heat and mass exchanger shown in FIGS. 6-9 may be employed.

The system diagram of FIG. 15 shows one preferred embodiment of an air conditioning system according to the present disclosure. The system utilizes the combination of a desiccant wheel and heat and mass exchanger (HMX) (preferably in accordance with a present design). The air flow patterns illustrate the implementation of indirect and direct evaporative cooling to serve the cooling needs of the residence. The air flow chart also shows the receipt of three air flow sources into the supply side of the heat and mass exchanger which may be modulated to achieve desired results. The heat and mass exchanger supply receives a portion from the outside ambient air and airflow passed through the desiccant wheel. Moreover, both cooler recycled air and outside air are passed through the desiccant wheel before receipt by the heat exchanger. The HMX outlets moist air, and supplies dryer air at about 66 to 75° F. (in one embodiment).

The system diagram of FIG. 16 illustrates an alternative embodiment that may be referred to as a “super cooling” system. The system utilizes a second heat and mass exchanger positioned upstream of the desiccant wheel. The first heat exchanger receives both return air from the residence and outdoor air, and passes pre-conditioned, cooler air to the desiccant wheel. The desiccant wheel receives the pre-cooled air as well as a portion of the outdoor air and outputs hotter drier air. This dry air is then passed through the second heat and mass exchanger which outputs cool, dry air for the residence.

The system diagram of FIG. 17 illustrates an alternate embodiment, which in one respect is a modification of the system of FIG. 15 (which employs “natural” cooling). The system employs direct evaporator cooling.

FIGS. 20-26 are simplified illustrations of an indirect direct evaporative air conditioner system (IEC) according to the present disclosure. This equipment may be employed in one or more of the systems described herein. Referring to FIG. 19A, the heart of the system is a rectangular core. The preferred core structure is shown in more detail in FIGS. 19B-19E. In preferred constructions, the module provides a steel enclosure for a natural fiber hygroscopic membrane, with plastic vent panels and plastic separators. As shown, the generally rectangular enclosure has a horizontal or length dimension that is greater than a height or vertical direction or width direction (into the age in the side view Figures). In the embodiment shown, the module is equipped with two air inlets 1000 a and 1000 b (hot air inlets) on a vertical end surface, an exhaust outlet 4000 (cold wet exhaust outlet) on top surface, and two outlets 2000 (cold dry air outlet) and 3000 (cold wet air outlet) preferably located on a vertical end surface opposite of the inlets (FIG. 25). As generally known in the relevant art, the configuration provides channels in between spaced-panels that define at pre-determined air flow paths 5000 a, 5000 b, and 5000 c (FIG. 25) between the inlets and the exhaust and the inlets and the outlets. At least one air flow path exits as cooled air supply through an outlet to the residence and another air flow path exits as warmed air through the exhaust or, in several embodiments or modes of operation, for further utilization by the system. The flow paths are illustrated in general fashion in the schematics of FIGS. 20-26. These simplified diagrams also illustrate the various operational modes of the IEC, which include the following:

-   -   Air Pass Through Mode (see dry fresh outside air inlet 2010 and         cool fresh air outlet 2012)     -   Direct Evaporative Cooling (DEC) Mode (Swamp         Cooler/Dehumidifier)     -   Indirect Evaporatice Cooling (IEC) Mode (Dew Point Cooling)     -   IEC/DEC Mode

Accordingly, with use of the improved IEC Module, several evaporation and cooling techniques may be employed or achieved. One or more of these techniques are illustrated in the Figures and include the following:

-   -   Increased Evaporation Air Flow,     -   Modulated Preheating of Working Air,     -   Increased Evaporation Surface,     -   Dehumidification of Working and Process Air,     -   Water (Refrigerant) Treatment; and     -   Creation of a Vacuum to reduce evaporation area pressure.

Furthermore, several embodiments of the module and systems incorporating the module are generally suited to further employing waste heat (i.e., as described previously herein) as energy source and reducing loads and reliance on the electric grid. Operation of several of such systems for cooling the residence results in little or no exhaust to the outside. Such systems also serve humidifying and dehumidifying needs of eth residence without additional fuel consumptions. Moreover, the use of water as the predominant working fluid, rather than a traditional synthetic refrigerant, is beneficial to the environment.

In an alternative embodiment, as illustrated in FIG. 27, the system employs a vacuum cooler in a closed loop system (waste heat evaporator), which uses water as the operating fluid—refrigerant. More particularly, the heat and mass exchanger is modified to operate with a vacuum cooler adjacent and upstream of a liquid desiccant absorber. As shown, a vacuum pump is operated with the vacuum cooler. The liquid desiccant absorber received mixed hot humid outside air and indoor air via inlet 7000 a, as well as solely outside air via line 7000 b (FIG. 28). As shown in the system diagram, a heat exchanger is positioned to interact with (and heat) liquid desiccant. Warmer desiccant concentrate is communicated to the liquid desiccant absorber and cooler desiccant dilute is returned. Cool dry air is discharged from the vacuum cooler to the target environment. The system is also equipped with a condenser and vapor separator to treat and cycle system water passing from and to the vacuum cooler. In a further alternative embodiment, as illustrated in FIG. 28, the closed loop system employs an indirect evaporative cooler in place of the vacuum cooler. Humid cool air is exhausted from the cooler and cool dry air is supplied to the target environment.

In a method operating the closed loop system of FIG. 27 or 28, the system recovers condensate absorbed by the desiccant. Minimizing liquid desiccant exposure, the closed loop system reduces the corrosion effects on system components and associated systems and equipment, and other damage otherwise caused by liquid desiccant exposure. The system also reduces system water loss and produces clean distilled water.

The foregoing description has been presented for purposes of illustration and description of preferred embodiments. This description is not intended to limit associated concepts to the various systems, apparatus, structures, and methods specifically described herein. For example, system and methods described in the context of a residence, may be applicable, in part or in entirety, to other permanent or stationary installations, such as commercial office building, factory, warehouse or other workplace, or such non-permanent but defined localized environments, as long-haul trucks or similar powered mobile vehicles. The embodiments described and illustrated herein are further intended to explain the best and preferred modes for practicing the system and methods, and to enable others skilled in the art to utilize same and other embodiments and with various modifications required by the particular applications or uses of the present invention. 

1. A method of generating and distributing electric power to meet localized demand, said method comprising: providing a local environment having an air conditioning unit for supplying cooled air within the local environment, the unit including a closed loop circuit configured to operate a closed loop refrigeration cycle, including a compressor operable to compress a working fluid of the closed loop circuit; engaging an internal combustion engine with the compressor; and operating the internal combustion engine to drive the compressor, thereby transferring energy to the refrigeration cycle.
 2. A system for generating electric power in a localized installation, said system comprising: a hybrid power generator; an air conditioning cooling system, including a compressor; and a selectively engageable drive assembly operably connected with the power generator, whereby the power generator is enageable with the compressor to compress a working refrigerant fluid; and wherein the hybrid power generator includes an internal combustion engine and an electric motor, the drive assembly being operable to selectively engage the electric motor and the internal combustion engine with the compressor.
 3. A system for supplying cooling air to a residence or building interior comprising: a heat and mass exchanger positioned to discharge conditioned air into the residence or building interior; and a rotatable desiccant wheel dehumidifier; wherein the desiccant wheel dehumidifier is positioned and configured to receive supply air for treatment, exhaust hot, humid air, and supply dry air to the heat and mass exchanger; and wherein the heat and mass exchanger is positioned and configured to receive dry air from the dehumidifier and supply cooler dry air to the residence or building interior.
 4. The system of claim 3, wherein the dehumidifier is positioned and configured to receive dry recycled air from the residence or building interior.
 5. The system of claim 3, wherein the dehumidifier is positioned and configured to receive outdoor air for treatment.
 6. The system of claim 3, wherein the dehumidifier is positioned and configured to receive less than about 80 to 85 def. F dry recycled air and deliver above 100 deg. F dry air to the heat and mass exchanger and the heat and mass exchanger is positioned to supply dry air below about 78 deg. F to the residence or building interior.
 7. The system of claim 3, further comprising a second heat and mass exchanger positioned upstream of the dehumidifier to deliver supply air to the dehumidifier and configured to receive return air from the residence or building interior and outdoor air for treatment.
 8. The system of claim 3, wherein the heat and mass exchanger includes a vacuum chamber positioned on a discharge side from which said cool supply air discharged to the residence or building interior travels.
 9. The system of claim 3, wherein the heat and mass exchanger includes a vacuum chamber positioned on an exhaust side through which exhaust air exits.
 10. The system of claim 3, wherein the heat and mass exchanger is configured in direct evaporative cooling mode.
 11. The system of claim 3, wherein the heat and mass exchanger is configured and operable in indirect evaporative cooling mode, including inlet ports to receive hot dry air and hot outside air, an exhaust to discharge wet cool exhaust, and an outlet to discharge cool dry air.
 12. The system of claim 3, wherein the heat and mass exchanger is configured and operable in indirect/direct evaporative cooling mode, including inlet ports to receive hot dry air and hot outside air, an exhaust to discharge wet cool exhaust, and outlet ports to discharge cool dry air and cool wet air.
 13. The system of claim 3, wherein the heat and mass exchanger is configured and operable in enthalpy mode, including inlet ports to receive hot outside air, an exhaust to discharge wet cool exhaust, an outlet to discharge cool dry air, and an auxiliary port selectively positionable and operable to receive stale indoor air into the heat and mass exchanger.
 14. (canceled)
 15. (canceled)
 16. (canceled)
 17. (canceled)
 18. (canceled)
 19. (canceled)
 20. (canceled)
 21. (canceled)
 22. (canceled)
 23. (canceled)
 24. (canceled) 